Hazem (from Lan Wei’s group) presented his talk on testing and modeling cryogenic CMOS characteristics.

Both talks were well received, and led to further discussions.

Sean successfully defended his PhD thesis, entitled “Scanning tunneling microscopy of electrically driven phase transitions in a charge density wave material” on March 3, 2022. His PhD is in Chemistry with a Quantum Information specialization.

Part of his thesis work has also been published in the prestigious journal Nano Letters – Observation and manipulation of a phase separated state in a charge density wave material

First, an entangled state of two spins is created by loading the electrons into the same dot, which leads to a spin singlet state via the Pauli exclusion principle. The electrons are then separated and shuttled to different nodes, thereby providing entanglement between the nodes.

After two entanglement distribution steps, a set of local operations is carried out on each node. First we form an entangled state of 4 qubits (spread over the 4 nodes); this is called a Greenberger-Horne-Zeilinger (GHZ) state, and is a key resource for the error correcting “surface code”.

Next, we perform conditional quantum logic operations between the “data” qubit in green, and the neighbouring ancilla qubit in red. Measuring the ancilla qubit on all four nodes tells us if an error has occurred or not, and provides information about the type of error so that it can be coherently corrected.

This animation provides a snapshot of what the operations would look like on a single 4-node “cell”. A large-scale quantum processor would consist of a 2D array of thousands or millions of such cells, all operating in parallel.

Credit: Joanna Roy, Ben van Osch, Annelise Bergeron

Bohdan’s MSc thesis entitled “Heterostructure development and quantum control for semiconductor qubits” was defended on Dec. 7. Bohdan was co-supervised by Prof. Zbig Wasilewski.

Alex’s MSc thesis entitled “Characterization of gate oxides and microwave resonators for silicon spin qubit devices” was defended on Jan. 6.

]]> https://research.iqc.uwaterloo.ca/csg/?feed=rss2&p=796 0 https://research.iqc.uwaterloo.ca/csg/?p=786 https://research.iqc.uwaterloo.ca/csg/?p=786#comments Tue, 29 Jun 2021 21:07:24 +0000 http://research.iqc.uwaterloo.ca/csg/?p=786 Continue reading →]]> UPDATE: this paper is now published in Applied Physics Letters!

A preprint describing our recent work on single electron pumps in dopant-free GaAs 2D electron gases is now available on the arxiv. Here is the abstract:

We have realized quantized charge pumping using non-adiabatic single-electron pumps in dopant-free GaAs two-dimensional electron gases (2DEGs). The dopant-free III-V platform allows for ambipolar devices, such as p-i-n junctions, that could be combined with such pumps to form electrically-driven single photon sources. Our pumps operate at up to 0.95 GHz and achieve remarkable performance considering the relaxed experimental conditions: one-gate pumping in zero magnetic field and temperatures up to 5K, driven by a simple RF sine waveform. Fitting to a universal decay cascade model yields values for the figure of merit δ that compare favorably to reported modulation-doped GaAs pumps operating under similar conditions. The devices reported here are already suitable for optoelectronics applications, and with further improvement could offer a route to a current standard that does not require sub-Kelvin temperatures and high magnetic fields.

“Quantum phenomena are typically observable at length and time scales smaller than those of our everyday experience, often involving individual particles or excitations. The past few decades have seen a revolution in the ability to structure matter at the nanoscale, and experiments at the single particle level have become commonplace. This has opened wide new avenues for exploring and harnessing quantum mechanical effects in condensed matter. These quantum phenomena, in turn, have the potential to revolutionize the way we communicate, compute and probe the nanoscale world. Here, we review developments in key areas of quantum research in light of the nanotechnologies that enable them, with a view to what the future holds. Materials and devices with nanoscale features are used for quantum metrology and sensing, as building blocks for quantum computing, and as sources and detectors for quantum communication. They enable explorations of quantum behaviour and unconventional states in nano- and opto-mechanical systems, low-dimensional systems, molecular devices, nano-plasmonics, quantum electrodynamics, scanning tunnelling microscopy, and more. This rapidly expanding intersection of nanotechnology and quantum science/technology is mutually beneficial to both fields, laying claim to some of the most exciting scientific leaps of the last decade, with more on the horizon.”